Disc distraction device

ABSTRACT

A disc distraction device comprising a first pedicle screw having a mounting end and a head end, a second pedicle screw having a mounting end and a head end, a rigid interconnection member coupled proximate the head end of both the first and second pedicle screws, and a spring member coupled to the first and second pedicle screws closer to the mounting ends of the pedicle screws than the rigid interconnection member.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation application of U.S. patent application Ser. No. 13/015,197, filed Jan. 27, 2011, titled “Self Distracting Pedicle Screw Distraction Device,” which is a continuation-in-part application of U.S. patent application Ser. No. 12/492,909, filed Jun. 26, 2009, titled “Vertebral Disc Tensioning Device,” now U.S. Pat. No. 7,896,904, issued Mar. 1, 2011, which is a continuation-in-part application of U.S. patent application Ser. No. 11/646,750, filed Dec. 28, 2006, titled “Vertebral Disc Annular Fibrosis Tensioning and Lengthening Device,” now U.S. Pat. No. 7,666,211, issued Feb. 23, 2010.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates generally to a pedicle screw distraction device that causes distraction between opposing vertebrae and, more particularly, to a pedicle screw distraction device that causes distraction between opposing vertebrae, where the device includes a connector link having a locking plate for locking pedicle screw heads to the link and an angled end that provides a desired angle between the pedicle screws.

2. Discussion of the Related Art

The human spine includes a series of vertebrae interconnected by connective tissue referred to as intervertebral discs that act as a cushion between the vertebrae. The discs allow for movement of the vertebrae so that the spine can bend and rotate.

The intervertebral disc is an active organ in which the normal and pathologic anatomies are well known, but the normal and pathologic physiologies have not been greatly understood. The intervertebral disc permits rhythmic motions required of all vertebrate animals in their various forms of locomotion. The disc is a high-pressure system composed primarily of absorbed water, an outer multilayered circumferential annulus of strong, flexible, but essentially inelastic collagen fibers, and an inner core of a hydrogel called the nucleus pulposus. The swelling of the contained hydrogel creates the high pressure that tightens the annular fibers and its laminations. Degeneration of discs in humans is typically a slow, complex process involving essentially all of the mechanical and physiologic components with loss of water holding capacity of the disc. Discogenic pain arises from either component, but is primarily due to altered chemistry. When this pain is severely disabling and refractory to non-operative, the preferred contemporary treatments are primarily surgical, particularly fusion and/or disc replacement.

Annular collagen fibers are arranged in circumferential belts or laminations inserting strongly and tangentially in right- and left-handed angulated patches into each adjacent vertebral body. Inside the annular ring is contained an aggrecan, glycosaminoglycan, a protein-sugar complex gel having great hygroscopic ability to hold water. The swelling pressure of this gel of the nucleus maintains the pressure within the annulus, forcing the vertebrae apart and tightening the annular fibers. This tightening provides the primary mechanical stability and flexibility of each disc of the spinal column. Further, the angulated arrangement of the fibers also controls the segmental stability and flexibility of the motion segment. Therefore, the motion of each segment relates directly to the swelling capacity of the gel and secondarily to the tightness of intact annulus fibers. The same gel is also found in thin layers separating the annular laminar construction, providing some apparent elasticity and separating the laminations, reducing interlaminar torsional abrasion. With aging or degeneration, nucleus gel declines by desiccation or the loss of water, while collagen content, including fibrosis, relatively increases.

Disc degeneration, which involves matrix, collagen and aggrecan, usually begins with annular tears or alterations in the endplate nutritional pathways by mechanical or patho-physiological means. However, the disc ultimately fails for cellular reasons. As a person ages, the discs in the spine go through a degenerative process that involves the gradual loss of the water holding capacity of the disc, referred to as desiccation. As a result of this loss of water, the disc space height may partially or completely collapse, which may lead to chronic back pain disorders and/or leg pain as a result of the nerves being pinched.

Progressive injury and aging of the disc occurs normally in later life and abnormally after trauma or metabolic changes. In addition to the chemical effects on the free nerve endings as a source of discogenic pain, other degenerative factors may occur. Free nerve endings in the annular fibers may be stimulated or irritated by stretching as the disc degenerates, bulges, and circumferential delamination of annular fibers occurs. This condition may lead to a number of problems. It has been shown that a person's disc is typically taller in the morning when a person awakes. This phenomenon may be due in part to the reduction of body weight forces on the disc when lying in a recumbent position overnight that causes the disc height to restore and provide rehydration. Therefore, the reduction of compressive forces on the disc may help to restore disc height and function.

As discussed above, as a person ages, the discs of the spine degenerate, and the disc space height collapses. Further, the ligaments and facets of the spine degenerate as well due to increased forces and stresses on these structures that occur as the disc loses its weight-bearing capacity. These problems can lead to a reduction in the foraminal height of the vertebrae. The neuro-foramen is an opening through the vertebrae that allows the nerve root of the spine to pass through. Because the nerve passes through the foramen, the nerve will often get pinched as the disc height collapses, leading to various types of back pain. Further, these problems often lead to difficulty in walking. Additionally, lateral and central canal stenosis can occur as a result of disc degeneration and collapse further causing the nerve roots to get pinched in the spinal canal. These conditions can lead to a condition referred to neurogenic claudication, where a patient can only walk a short distance before experiencing considerable back and leg pain. Typically, patients respond by sitting down and bending forward resulting in flexing of the spine and reducing pressure on the nerves relieving their symptoms.

The treatment of degenerative disc disease and associated spine ailments is one of the most costly medical conditions with an estimated annual direct cost in the United States of thirty-three billion dollars and a total annual societal cost exceeding one hundred billion dollars. Indeed, in one's lifetime most individuals will experience an episode of significant back and/or neck pain.

SUMMARY OF THE INVENTION

In accordance with the teachings of the present invention, a disc distraction device is disclosed comprising a first pedicle screw having a mounting end and a head end, a second pedicle screw having a mounting end and a head end, a rigid interconnection member coupled proximate the head end of both the first and second pedicle screws, and a spring member coupled to the first and second pedicle screws closer to the mounting ends of the pedicle screws than the rigid interconnection member.

Additional features of the present invention will become apparent from the following description and appended claims, taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a pedicle screw employed in a vertebral disc annular fibrosis tensioning and lengthening device;

FIG. 2 is a perspective view of a spring employed in the vertebral disc annular fibrosis tensioning and lengthening device;

FIG. 3 is a side view of the vertebral disc annular fibrosis tensioning and lengthening device of the invention including two of the pedicle screws with the spring therebetween;

FIG. 4 is a cross-sectional side view of the vertebral disc annular fibrosis tensioning and lengthening device shown in FIG. 3;

FIG. 5 is a top view of the vertebral disc annular fibrosis tensioning and lengthening device shown in FIG. 3;

FIG. 6 is a perspective view of a vertebral disc annular fibrosis tensioning and lengthening device, according to another embodiment;

FIG. 7 is a side view showing a vertebral disc annular fibrosis tensioning and lengthening device of the invention inserted within adjacent vertebrae;

FIG. 8 is a top view of two vertebral disc annular fibrosis tensioning and lengthening devices of the invention inserted within the adjacent vertebrae;

FIG. 9 is a perspective view of a vertebral disc annular fibrosis tensioning and lengthening device, according to another embodiment;

FIG. 10 is a cross-sectional view of the vertebral disc annular fibrosis tensioning and lengthening device shown in FIG. 9;

FIG. 11 is a perspective view of a plate member used in the device shown in FIGS. 9 and 10;

FIG. 12 is a perspective view of a spring element used in the device shown in FIGS. 9 and 10;

FIG. 13 is a perspective view of a vertebral disc annular fibrosis tensioning and lengthening device, according to another embodiment;

FIG. 14 is a broken-away, perspective view of a vertebral disc annular fibrosis tensioning and lengthening device, according to another embodiment;

FIG. 15 is a perspective view of a disc height restoration assembly;

FIG. 16 is a side view of a vertebral disc tensioning device, according to another embodiment;

FIG. 17 is a top view of the device shown in FIG. 16;

FIG. 18 is an exploded perspective view of the device shown in FIG. 16;

FIG. 19 is a cross-sectional view of the device shown in FIG. 16;

FIG. 20 is a perspective view of a pedicle screw and screw head portion in the device shown in FIG. 16;

FIG. 21 is a connector in the device shown in FIG. 16;

FIG. 22 is a bolt in the device shown in FIG. 16;

FIG. 23 is a spring assembly in the device shown in FIG. 16;

FIG. 24 is a side view of the device shown in FIG. 16 with the spring head portion pivoted relative to the connector;

FIG. 25 is a cross-sectional view of the illustration shown in FIG. 24;

FIG. 26 is a side view of a pedicle screw distraction assembly;

FIG. 27 is a top view of the assembly shown in FIG. 26;

FIG. 28 is a cross-sectional view of the assembly shown in FIG. 26;

FIG. 29 is an exploded perspective view of the assembly shown in FIG. 26;

FIG. 30 is a perspective view of a pedicle screw and screw head portion separated from the assembly shown in FIG. 26;

FIG. 31 is a perspective view of a screw link separated from the assembly shown in FIG. 26;

FIG. 32 is a perspective view of a locking member separated from the assembly shown in FIG. 26;

FIG. 33 is a side view of the locking member shown in FIG. 32 with a spring positioned therein;

FIG. 34 is a cross-sectional, perspective view of a portion of the assembly shown in FIG. 26 with a screw head portion in an insertion position;

FIG. 35 is a cross-sectional, perspective view of the portion of the assembly shown in FIG. 34 with the screw head portion in a working position;

FIG. 36 is a cross-sectional, perspective view of the assembly shown in FIG. 26 with the locking member holding the screw head portions in the working position; and

FIG. 37 is a perspective view of one of the screw head portions separated from the assembly shown in FIG. 26.

DETAILED DESCRIPTION OF THE EMBODIMENTS

The following discussion of the embodiments of the invention directed to a self distracting pedicle screw distraction device is merely exemplary in nature, and is in no way intended to limit the invention or its applications or uses.

FIG. 1 is a perspective view of a pedicle screw 10 for use in a vertebral disc annular fibrosis tensioning and lengthening device (FIG. 3). The pedicle screw 10 includes a threaded and tapered body portion 12 having a tip 14. The body portion 12 includes a plurality of holes 24 that allow bone to grow therein when the screw 10 is threaded into the vertebral body so that the pedicle screw 10 is better anchored within the vertebra. The use of holes in the body portion of a pedicle screw to facilitate bone growth therein can be employed in other types of pedicle screws for other uses besides vertebral disc annular fibrosis tensioning and lengthening devices, such as spinal fusion pedicle screw and rod instrumentation, well known to those skilled in the art. The holes 24 can come in a variety of numbers, diameters and configurations. In one non-limiting embodiment, the diameter of the body portion 12 is about 8 mm and the diameter of the holes is about 1.0 mm. The pedicle screw 10 can include a bore 26 that extends through the body portion 12 to make it cannulated so that a K-wire (not shown) can extend therethrough to allow for percutaneous placement of the pedicle screw over a K-wire that has previously been placed through the vertebral pedicle. This will allow for a minimally invasive application of the device that causes less disruption of the normal anatomical structures of the spine and improved recovery, as is well understood to those skilled in the art.

The pedicle screw 10 further includes a screw head 16 having an extended cup shape defining a cavity 18. The cavity 18 includes an open side 20 that fits a spring head (discussed below) and allows for mobility between the spring head and the cavity 18 of the screw head 16. This will permit mobility and will not limit flexion, extension and/or rotational mobility of the spine, thus allowing for the creation of a posterior motion-preserving device for reasons that will become apparent from the discussion below. An annular recess 22 is formed around an outside of the head 16 also for reasons that will become apparent from the discussion below. The pedicle screw 10 can be made of any suitable material, such as titanium, stainless steel, etc., as would be well understood to those skilled in the art. The cavity 18 could be made of ceramics or cobalt steel or cobalt chrome to limit wear between the spring head and the cavity 18.

FIG. 2 is a perspective view of a spring 30 having a cylindrical body 32 that is also part of the vertebral disc annular fibrosis tensioning and lengthening device. A series of slots 34 are cut into the body portion 32, as shown, in an alternating configuration that allows the body portion 32 to be compressed and provide an expansive spring force. The spring 30 includes generally rounded ends 36 and 38 that are shaped to conform to the shape of the inner surface of the cavity 18. The spring 30 can be made of any suitable material for the purposes described herein, such as nitinol, which is a flexible metal having a memory. Other materials may also be suitable, such as a shape memory alloy, polymers, hydrogels, etc., which could expand over time and allow for separation of the screw heads and disc height restoration. An example of a suitable alloy includes about 50% nickel and about 50% titanium.

FIG. 3 is a side view, FIG. 4 is a cross-sectional view, side view and FIG. 5 is a top view of a vertebral disc annular fibrosis tensioning and lengthening device 40, according to an embodiment. The vertebral disc annular fibrosis tensioning and lengthening device 40 includes two of the pedicle screws 10 where the open sides 20 of the heads 16 face each other, as shown. The spring 30 is inserted into the cavities 18 of the heads 16 so that the ends 36 and 38 conform to the inner surface of the cavities 18. The inner surface of the cavities 18 and the ends 36 and 38 can be coated with a suitable low friction material, such as chrome, cobalt, ceramic, etc., to prevent or reduce wear particle formation as the spring 30 and the pedicle screws 10 rub against each other. Initially, the spring 32 is compressed so that it provides an expansive force to separate the pedicle screws 10. In one non-limiting embodiment, the expanded or relaxed length of the spring 30 is in the range of about 3 cm-4 cm, which is about the height of a normal lumbar disc. The diameter of the spring 32 can be any diameter suitable for the purposes described herein.

An oval posterior ring 42 is positioned within the recesses 22, and operates to maintain the screws 10 in their proper orientation, and prevent the pedicle screws 10 from separating beyond a predetermined limit. The fixed diameter of the ring 42 allows for the tips 14 of the pedicle screws 10 to separate greater relative to the heads 16. This imparts lordosis. Further, as the spring 30 causes the pedicle screws 10 to separate, the ring 42 maintains the top end of the pedicle screws 10 stationary to create a pivot and restore the height of the disc and lordosis of the spine. Also, the configuration and orientation of the spring 30, the ring 42 and the screws 10 preserves the motion of the spine as the person performs normal physical movement in that it allows for continued flexion, extension, as well as axial rotation of the spine. The spring 30 operates as a compressible link and the posterior ring 42 operates as a rigid link.

FIG. 6 is a perspective view of a vertebral disc annular fibrosis tensioning and lengthening device 50, according to another embodiment, where like elements to the vertebral disc annular fibrosis tensioning and lengthening device 40 are identified by the same reference numeral. In this embodiment, the heads 16 of the pedicle screws 10 include a slot 52. The ring 42 is replaced with a dumbbell member 54 including a cylindrical body portion 56 and end portions 58 and 60. The body portion 56 extends through the slots 52 so that the end portions 58 and 60 are positioned on outside sides of the heads 16, and also operates to limit the expansion of the pedicle screws 10 and control the posterior aspects of the screws 10 and control the posterior aspects of the screws 10, thus allowing restoration of the lordosis, i.e., normal curvature, of the spine.

FIG. 7 is a side view and FIG. 8 is a top view of two of the vertebral disc annular fibrosis tensioning and lengthening devices 40 coupled to two adjacent lumbar vertebra 70 and 72 having a disc 68 therebetween. The pedicle screws 10 are threaded through pedicles 74 of the vertebra 70 and 72 and into the vertebral body 76. Once the pedicle screws 10 are in place, then the spring 30 is positioned within the cavities 18 under compression, as discussed above. As the spring bias forces the vertebra 70 and 72 apart, the height of a disc space 78 between the vertebra 70 and 72 increases and is restored. Further, as the height of the disc space 78 increases, the disc 68 is able to regenerate due to reduced sheer or compressive forces applied to the disc 68. The device 40 creates a controlled distraction force and distraction distance on the annulus fibrosis and a controlled dynamic motion of the vertebra. Further, the device 40 allows motion of the spine while maintaining the stress tension effect on the disc 68. Particularly, the device 40 provides a tension force across a compromised vertebral disc providing a distractive force to elicit the stress tension effect on the annulus fibrosis. The pedicle screws and links therebetween are arranged in a parallelogram shape to provide the desired distraction. Because most systems work like a hinge, the front or anterior portion of the disc moves much more than the back or posterior portion of the disc. This is not a natural motion, so with the vertebral linkage of the invention, a parallel or near parallel motion of the disc can be achieved. In one non-limiting embodiment, the motion pathway is an arc of a radius much longer than the pedicle screw length. Although the device 40 is shown coupled to adjacent vertebra, the device 40 can extend across any suitable number of vertebrae to increase the disc space of more than one disc.

The device 40 can also be applied unilaterally to restore coronal alignment. This is particularly applicable to patients suffering from scoliosis where the curvature of the spine could be corrected by applying the device 40 to the concaved portion of the spine. Restoration of spinal alignment would ultimately open the neural foramina on the concaved side and help to alleviate symptoms of lower back pain experience by these patients.

Any suitable surgical procedure for placing the pedicle screws 10 can be used, including minimally invasive surgical procedures by making the pedicle screws 10 cannulated. In one known process of percutaneous pedicle screw instrumentation, a Jamshidi needle is used to dock on to the junction of the vertebrae between the facet complex and the transverse process of the vertebra. Gentle taps with a mallet cause the Jamshidi needle to be advanced through the pedicle 74, making sure not to cross the medial border of the pedicle 74, which can result in nerve root injury, until the junction between the pedicle base and the vertebral body is reached. Fluoroscopic visualization into the anterior posterior and lateral planes of the vertebra is used to see the orientation of the Jamshidi needle. The correct trajectory of the Jamshidi needle should place the tip of the needle in the center of the pedicle in the anterior posterior view when the tip of the Jamshidi needle lies at the pedicle vertebral body junction in the lateral view.

Once the junction between the base of the pedicle wall and the vertebral body is reached, the Jamshidi needle can be directed in a more medial fashion. The Jamshidi needle is typically passed to about one-half the depth of the vertebral body, and then a K-wire is passed down the Jamshidi needle and into the vertebral body a little farther to seat it into the bone. The Jamshidi needle is then removed. A series of cannulated muscle dilators are then passed over the K-wire to prevent the soft tissue from going into the threads of the tap. The pedicle is tapped and a cannulated pedicle screw is then passed down the dilators.

Although a specific type of spring has been described above for the vertebral disc annular fibrosis tensioning and lengthening device, the present invention contemplates any suitable linearly expandable link suitable for the purposes described herein. The link exerts a force creating a stress tension effect within the disc allowing it to regenerate according to Wolff's law. The link also allows parallel distraction of the disc, distraction along the coronal plane of the disc tissue, and puts the annulus fibrous in tension and provides torsional rotation of the vertebral construct. Further, the pedicle screws can be replaced with any suitable mounting member. By a more general description, the vertebral disc annular fibrosis tensioning and lengthening device includes a caudle vertebral body attachment member and a cephelad vertebral body attachment member having a non-rigid interconnection member therebetween that creates the tension stress effect on the annulus fibrosis. The posterior ring 42 acts as a rigid member coupled between the attachment members that also operates to provide the distractive force.

FIG. 9 is a perspective view and FIG. 10 is a cross-sectional view of a vertebral disc annular fibrosis tensioning and lengthening device 80, according to another embodiment, that illustrate other designs that provide the annular fibrosis tensioning and lengthening and restore the natural lordosis of the spine in the manner discussed above. The device 80 includes a pair of pedicle screws 82 each including a body portion 84 having a ball head 86. The pedicle screw 82 also includes a pedicle screw head portion 88 having an internal threaded bore 90 through which the body portion 84 extends so that the ball head 86 is mounted on a shoulder 92 within the bore 90, as shown. A collar 94 is threaded into the internal bore 90 of the pedicle screw head portion 88 and engages a slot 96 in the ball head 86 to rigidly hold the body portion 84 in place at a proper kyphotic angle. The body portion 84 includes an internal bore 98 that accepts the Jamshidi needle for the reasons discussed above.

When the pedicle screws 82 are properly placed in the vertebrae during the surgical procedure, a plate connector 100, shown separated from the device 80 in FIG. 11, is positioned over the pedicle screw head portions 88 so that holes 102 and 104 in ends 108 and 110, respectively, in the plate connector 100 line up with the bores 90 in the pedicle screw head portions 88. Bolts 106 are then placed through the holes 102 and 104 and threaded into the threaded bores 90 in the pedicle screw head portions 88 to secure the plate connector 100 to the pedicle screws 82. The plate connector 100 has a gradual U-shape, as shown, where the ends 108 and 110 are slightly angled upward to provide the proper orientation for the device 80 that sets the maximum distraction of the disc.

In order to provide the distraction, a U-shaped spring element 112, shown separated from the device 80 in FIG. 12, is inserted between the pedicle screw head portions 88, where legs 114 and 116 of the spring element 112 push against the head portions 88, which cause the pedicle screw body portions 84 to pivot away from each other and cause the disc height to be restored in a lordotic manner. As the spring element 112 separates the pedicle screws 82 to provide the distraction, the pedicle screw head portions 88 pivot on the plate 100 to provide the desired distraction. Thus, the combination of the plate 100 and the spring element 112 provide the expandable and rigid link that operates in the manner as discussed above.

FIG. 13 is a perspective view of a vertebral disc annular fibrosis tensioning and lengthening device 120, according to another embodiment, where like elements to the device 80 are identified by the same reference numeral. In the device 120, the spring 112 and the plate 100 are combined or integrated into a single integrated element 122. The plate part of the integrated element 122 is flat in this embodiment and includes end pieces 124 and 126 through which the bolts 106 are placed. The element 122 includes limit stops 128 and 130 that limit the amount of distraction of the disc and also prevent overloading during jumping and other high loading states. The spring part of the integrated element 122 includes a live spring element 132 that provide the disc distraction. In this embodiment, an increased spring effect is provided by a spring loop portion 134 that extends the length of the spring element 132 to increase the distractive force.

The device 120 also includes an optional wedge member 136 positioned between one of the screw head portions 88 and the integrated element 122, as shown. The wedge 136 is placed by the surgeon to provide changes in both height and angulations simultaneously, if desirable.

FIG. 14 is a perspective view of a vertebral annular fibrosis tensioning and lengthening device 150, according to another embodiment, where like elements to the devices 80 and 120 are identified by the same reference numeral. In this embodiment, the screw head portion 88 is replaced with a rounded screw head portion 152. The screw head portion 152 includes a cylindrical cap portion 154 having an internal threaded bore 156. A plate 158 is mounted to the cap portions 154 so that holes 160 and 162 in the plate 158 line up with the bores 156. Bolts 164 are threaded into the bores 156 to secure the plate 158 to the screws 82. A cylindrical spring element 168 having spaced apart slots 170 is positioned between the rounded screw head portions 152, as shown, where the spring element 168 is held in place by the relative shape between the ends of the spring element 168 and the head portions 152. The spring element 168 provides the distractive force and the plate 158 provides the pivot limiting force as described above.

FIG. 15 is a perspective view of a disc height restoration assembly 180 including a plurality of pedicle screws 182 each including a body portion 184 and a head portion 186. The head portion 186 includes an open U-shaped channel 188 defining opposing side walls 190 and 192 that allow adjacent pedicle screws 182 to be positioned together, as shown. A clip member 194 is positioned over adjacent side walls 192 of adjacent pedicle screws 182 to clip the adjacent pedicle screws 182 together and provide a distracted force to the disc when the pedicle screws 182 are mounted to adjacent vertebrate. A spring element 196 is included.

FIG. 16 is a side view, FIG. 17 is a top view, FIG. 18 is a blown-apart perspective view and FIG. 19 is a cross-sectional perspective view of a vertebral disc annular fibrosis tensioning and lengthening device 200, according to another embodiment. The device 200 is operable to provide the disc tensioning and lengthening as discussed above to restore the natural lordosis of the spine. The device 200 includes a pair of pedicle screws 202 each having a body portion 204 and a ball head 206. An internal bore 208 extends through the body portion 206 and the ball head 206 to accept a K-wire as discussed above. The device 200 also includes a screw head portion 210 having an internal threaded bore 212. FIG. 20 is a perspective view of one of the pedicle screws 202 and one of the screw head portions 210 separated from the device 200. The body portion 204 of the screw 202 is inserted through a top end of the internal bore 212 until the ball head 206 rests against a narrowed shoulder 214 in the head portion 210 that allows the pedicle screw 202 to be pivoted relative to the screw head portion 210, as discussed above. The screw head portion 210 further includes a lateral cavity 216 that accepts a spring, as will be discussed in detail below. The screw head portion 210 also includes a concave shaped top surface 218 also provided for reasons that will become apparent for discussion below.

The vertebral disc annular fibrosis tensioning and lengthening device 200 also includes a screw connector 220 shown separated from the device 200 in FIG. 21. The connector 220 includes a top plate 222 and opposing side plates 224 and 226, as shown. A support member 228 is connected to the opposing side plates 224 and 226 opposite to the top plate 222. In other words, the plates 224 and 226 are interconnected with a cross-link from a construct on one side of the spinal cord to the other. The connector 220 includes a first opening 230 provided in a convex shaped portion 232 at one end of the top plate 222 and a second opening 234 provided in a convex shaped portion 236 at an opposite end of the top plate 222 for reasons that will become apparent from the discussion below. The top plate 222 also includes a slot 240 through which a wedge 238 is inserted into the device 200 to adjust a spring travel, as will also be discussed below.

The device 200 also includes a pair of bolts 260, where one of the bolts 260 is shown separated from the device 200 in FIG. 22. The bolt 260 includes a bolt body 262 and a bolt head 264. An internal bore 266 extends through the bolt 260 and aligns with the bore 208 in the pedicle screw 202. A half-mooned shaped collar 268 including an opening extending therethrough is positioned around the bolt body 262 just below the bolt head 264 of the bolt 260, as shown.

The device 200 also includes a spring assembly 270 shown separated from the device 200 in FIG. 23. The spring assembly 270 includes a base portion 272 having a bore 274 therein. The spring assembly 270 also includes a plunger 276 having a cylindrical body portion 280 and a head portion 278. A compressible spring member 282 including an internal bore 284 is provided between the head portion 278 and the base portion 272 where the body portion 280 extends through the bore 284 and into the bore 274, as shown. A compression force between the plunger 276 and the base portion 272 causes the head portion 278 to push against the spring member 282 so that the body portion 280 extends farther into the channel 274.

The device 200 is assembled so that the pedicle screws 202 are pivotally mounted within the screw head portions 210 and the spring member 282 is positioned within the opposing cavities 216 of the head portions 210 so that the head portion 278 of the plunger 276 is in one of the cavities 216 and the base portion 272 is in the other cavity 216 of the other screw head portion 210. The connector 220 is then positioned over the screw head portions 210 so that the side plates 224 and 226 are provided at sides of the screw head portions 210 and the top plate 222 covers the cavities 216 to hold the spring assembly 270 within the device 200. In this configuration, the shape of the concave shaped portions 232 and 236 conforms to the concave surfaces 218 of the screw head portions 210. The bolts 260 are then threaded into the threaded openings 212 through the openings 230 and 234 to hold the connector 220 to the screw head portions 210. A bottom end of the bolts 260 is rounded to conform with the shape of the ball heads 206. Thus, the ball heads 206 can rotate within the screw head portions 210 on the shoulders 214. When the bolts 260 are threaded into the openings 212, the half-moon portions 268 conform to an upper surface of the concave portions 232 and 236. Thus, the connector 220 provides the non-compressible link and the spring assembly 270 provides the compressible link as discussed above to provide the disc distraction and regeneration. The wedge 238 can be driven through the hole 240 to conform with the head portion 278 of the plunger 276 to reduce the travel of the spring 282 if desired.

In addition to the pedicle screw 202 being able to pivot relative to the screw head portion 210, the assembly of the pedicle screw 202, the screw head portion 210 and the bolt 260 can pivot relative to the connector 220. FIG. 25 is a cross-sectional view of the device 200 with the spring assembly 270 removed and FIG. 24 is a side view of the device 200 showing this feature. As is apparent, the orientation and shaping of the concave surfaces 218 on the screw head portion 210, the concave shaped portions 232 and 236 of the plate connector and the half-moon shape of the collars 268 allow the spring head portions 210 and the collars 268 to pivot relative to the connector 222 when the bolt 260 is threaded into the threaded bore 212.

FIG. 26 is a side view, FIG. 27 is a top view, FIG. 28 is a cross-sectional view and FIG. 29 is a blown-apart, perspective view of a self distracting pedicle screw distraction device assembly 300 that is operable to provide the disc tensioning and lengthening as discussed above to restore disc height and the natural lordosis of the spine. The device assembly 300 includes a pair of pedicle screws 302 each having a body portion 304 and a ball head 306. An internal bore 308 extends through the body portion 304 and the ball head 306 to accept a K-wire, as discussed above. The device assembly 300 also includes a pair of screw head portions 310 each having an internal threaded bore 312. FIG. 30 is a perspective view of one of the pedicle screws 302 and associated screw head portion 310 separated from the device assembly 300. The body portion 304 of the screw 302 is inserted through a top end of the internal bore 312 until the ball head 306 rests against a shoulder 314 at a bottom end of the head portion 310 that allows the pedicle screw 302 to be pivoted relative to the screw head portion 310. A threaded set screw 316 is threaded into the threaded bore 312 of the head portion 310 by inserting a wrench (not shown) into an opening 318 in the set screw 316 to lock the pedicle screw 302 at a specific angle relative to the head portion 310 against the shoulder 314.

A cylindrical protrusion 322 extends from an outside surface of the head portion 310 for reasons that will become apparent from the discussion below. Further, a bottom edge flange 324 is provided on one side of the head portion 310 and opposing top and bottom edge flanges 326 and 328 are provided at an opposite side of the head portion 310 to define a slot 330 therebetween, also for reasons that will become apparent from the discussion below.

The device assembly 300 also includes a screw link 340 shown separated from the device assembly 300 in FIG. 31. The screw link 340 is an elongated oval sleeve member having an outer perimeter portion 342 defining an internal slot 344. One end 346 of the link 340 is angled at location 348 relative to an opposite end 350 of the link 340 to provide an angled orientation between the pedicle screws 302 and a lordotic separation between the pedicle screws 302, as will be discussed in more detail below. An angled edge 352 and a slot 354 are provided on an inside surface of a side rail 356 at a central internal location of the perimeter portion 342, and an angled edge 358 and a slot (not shown) are provided on an inside surface of a side rail 360 of the perimeter portion 342 also for reasons that will become apparent from the discussion below. An arced brace 362 connects the opposing side rails 356 and 360 at a bottom location of the perimeter portion 342.

The device assembly 300 also includes an elongated locking member 370 shown separated from the device assembly 300 in FIGS. 32 and 33. The locking member 370 includes a locking plate 372 having an angled end 374 that conforms with the angled end 346 of the link 340. A separating portion 376 extends perpendicular from the locking plate 372 and includes a cylindrical opening 378 that conforms to and accepts a spring 380. The separating portion 376 includes a flange 382 opposite to the plate 372 and a tab 384 adjacent to the flange 382, as shown.

The locking member 370 locks the screw head portions 310 to the link 340 as shown in FIGS. 34, 35 and 36. During assembly, the screw head portion 310 is inserted up through the slot 344 in the link 340 where the side of the screw head portion 310 adjacent to the flange 324 rides along an inside surface of the rail 356 of the perimeter portion 342 until the flange 324 contacts a bottom surface of the rail 356. In this position, the opposing flanges 326 and 328 are provided above and below the opposite rail 360 of the perimeter portion 342 where the height of the rail 360 matches the width of the slot 330. The screw head portion 310 is then slid over so that the rail 360 slides into the slot 330 and the flanges 326 and 328 are positioned at top and bottom surfaces of the rail 360, as shown in FIG. 35. In this configuration, the flange 324 still contacts the bottom surface of the rail 356, but there is a gap between the outside surface of the screw head portion 310 and the rail 356.

With the spring 380 positioned within the cylindrical opening 378, the locking member 370 is inserted into the link 340 so that the plate 372 is positioned within the gap between the screw head portions 310 and the rail 356, and the separating portion 376 is positioned between the screw head portions 310. The tab 384 rides along the edge 352 and is inserted into the slot 354 on the rail 356 in a snap-fit engagement, and the opposing tab rides along the edge 358 and is inserted in the opposing slot in a snap-fit engagement to lock the locking member 370 to the connector link 342 and hold the entire assembly 300 together. The spring 380 is held in place within the opening 378 by the brace 362 where the protrusions 322 are positioned within opposite ends of the spring 380.

The spring 380 is under compression so that it applies a separating force to the screw head portions 310. In one non-limiting embodiment, the spring 380 has a spring constant value in the range of 0-1000 pounds/inch. The angle between the ends 346 and 350 of the link 340 causes the screws 302 to be separated in a lordotic manner under the bias of the spring 380 as dictated by the angle between the ends 346 and 350, where the angle can vary between 0° and 30°. The locking member 370 is configured so that the separating portion 376 is offset relative to the center of the plate 372, where one of the pedicle screws 302 and associated screw head portion 310 are positioned in a short segment between the separating portion 376 and the end 346 of the link 340 and the other pedicle screw 302 and associated screw head portion 310 are positioned in a long segment between the separating portion 376 and the end 350 of the link 340.

When the assembly 300 is being assembled during the surgical procedure in the manner as discussed above, the pedicle screw 302 and associated screw head portion 310 provided in the short segment is locked in place by positioning a series of detents 384 within corresponding openings (not shown) in an underside of the rail 360 of the length 340. When the surgeon is assembling the assembly 300 during the surgical procedure, he will insert the screw head portion 310 in the short segment of the link 340 in the desired positioned so that the detents 384 are positioned within the desired openings that allows an adjustment of the screw head portion 310 along the short segment. In one non-elimiting embodiment, the range of position of the screw head portion 310 is provided by four of the detents 384 and is about 0-8 mm. This is by way of a non-limiting example, where a different number of detents 384 possibly having a different spacing can provide other ranges. Once the locking member 370 is in place, the screw head portion 310 having the detents 384 is held in that position. The other screw 302 and screw head portion 310 positioned within the long segment in the link 340 is free to slide along the long segment. When the pedicle screws 302 are inserted into the pedicle of the vertebra, and the spring 380 provides the separating force between the screw head portions 310, the disc is distracted by the ability of the screw head portion 310 in the long segment to slide along the link 340, where the angle of the screws 302 as set by the set screws 316 and the angle between the ends 346 and 350 of the link 340 provide the separation in line lordotic manner.

The foregoing discussion discloses and describes merely exemplary embodiments of the present invention. One skilled in the art will readily recognize from such discussion and from the accompanying drawings and claims that various changes, modifications and variations can be made therein without departing from the spirit and scope of the invention as defined in the following claims. 

What is claimed is:
 1. A disc distraction device comprising a first attachment member having an end configured to be attached to one vertebral body, a second attachment member having an end configured to be attached to another vertebral body, a non-compressible rigid interconnection member coupled to both the first and second attachment members along a first axis proximate an end of the attachment members opposite to the ends configured to be attached to the vertebral bodies, and a compressible member coupled to the first and second attachment members along a second axis and under compression, wherein the second axis is spaced apart from the first axis and is closer to the ends of the attachment members configured to be attached to the vertebral bodies, and wherein a separating force provided by the compressible member when the compressible member is compressed causes the ends of the vertebral body attachment members configured to be attached to the vertebral bodies to separate and cause the first and second attachment members to pivot at the first axis.
 2. The device according to claim 1 wherein the compressible member is a spring.
 3. The device according to claim 1 wherein the first and second attachment members are pedicle screws.
 4. The device according to claim 1 wherein the compressible member is more compressible than the rigid interconnection member under the same force.
 5. A disc distraction device comprising a first attachment member having a mounting end and a head end, a second attachment member having a mounting end and a head end, a non-compressible rigid interconnection member coupled proximate the head end of both the first and second attachment members along a first axis running at least partly through the rigid interconnection member, and a compressible member coupled to the first and second attachment members along a second axis running at least partly through the compressible member, said compressible member being more compressible than the rigid interconnection member under the same force, wherein the second axis is spaced apart from the first axis and is closer to the mounting ends of the attachment members than the first axis, and wherein a separating force provided by the compressible member when the compressible member is under compression causes the mounting ends to separate and cause the first and second attachment members to pivot at the first axis.
 6. The device according to claim 5 wherein the compressible member is a spring.
 7. The device according to claim 5 wherein the first and second attachment members are pedicle screws.
 8. A disc distraction device comprising a first pedicle screw having a mounting end and a head end, a second pedicle screw having a mounting end and a head end, a non-compressible rigid interconnection member coupled proximate the head end of both the first and second pedicle screws, and a spring member coupled to the first and second pedicle screws closer to the mounting ends of the pedicle screws than the rigid interconnection member, wherein a separating force provided by the spring member when the spring member is under compression causes the mounting ends of the first and second pedicle screws to separate and cause the first and second pedicle screws to pivot at the rigid interconnection member. 